Abstract
The multinational Paraná River (drainage basin ~ 2.6 × 106 km2; current discharge ~ 540 km3 y−1) has in its middle and lower stretches a long (~ 1200 km) and wide (~ 30 – 50 km) flood valley mantled with riparian vegetation and fully carved with lentic and lotic water bodies. Most of the wetland (~ 50000 Km2) holds myriad water bodies which, following the seasonal variation of the prevailing discharge regime, exchange water, dissolved chemical species, sediment, and biological materials with the Paraná’s main stem. Exceptional hydrological events (e.g., strong El Niño-triggered floods) sporadically inundate almost totally the flood valley’s expanse. The examination of chemical data collected in the main channel during the 1982–1983 event showed: (a) TDS was diluted to almost ¼ of the original concentration during the high flood; (b) water pH decreased to ~ 6.5, and CO2 partial pressure increased up to ~ 16000 ppmv during the overbank stage and afterwards; (c) throughout the event water remained within the medium dilute/dilute water types (375 > TZ+ > 1500 µeq L−1); and (d) dissolved inorganic carbon (DIC)—along with other variables—reached the highest concentrations in the descending limb, when the floodplain was drained. Dissolved organic carbon (DOC) showed an uneven variability pattern, seemingly unrelated to DIC, but definitely influenced by the significant lentic–lotic exchange. A 10-year long (1965–1975), uninterrupted series of alkalinity measurements allowed probing into the mechanisms that contributed to determine the observed alkalinity variability. Such variation appeared controlled by several biogeochemical processes occurring in the wetland (e.g., photosynthesis/respiration), sporadically impacted by changing hydrological stages.
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Introduction
Rivers construct floodplains through a combination of erosion and deposition at lower gradient stretches of river valleys. A floodplain is a relatively low relief sedimentary plain, although it has a general downstream slope coherent with the overall river gradient. In large rivers, floodplains usually have a “topographic amplitude between ridges and the beds of floodplain water bodies of ~ 0.1–0.5 times the bank full depth of the river, constructed by various sedimentation processes and inundated to some extent by most annual floods in the current hydro climatic regime of the river’s drainage basin” (Dunne and Aalto 2013). Floodplains are filled with alluvium (i.e., loose sediments transported by streams), which is easily eroded and redeposited by the river. It follows that the location in a floodplain of a river main channel is not a stable feature and changes with a measurable rate (e.g., Paira and Drago 2007).
Flooding, besides being a normal characteristic of river behavior, occurs when the water depth in a river exceeds the depth of the waterway and spreads beyond the river main channel onto the surrounding land (e.g., Benke et al. 2000; Steiger et al. 2005). When a river fills completely its main stem, it is said to be at bank full stage; when it surpasses bank full stage it is said to be an overbank flood.
Abundant literature shows that flooding dynamics are considered to be the chief variable forcing the structure and functioning of floodplain systems (Dunne and Aalto 2013, and references therein). Overbank events force longitudinal, vertical, and lateral exchanges of material and energy, finally affecting—among several other impacts—patterns of sediment deposition and erosion (e.g., Potter et al. 2005), and biogeochemical cycling through space and time (e.g., Richards et al. 2003; Tank et al. 2010). Moreover, the time in which a floodplain remains inundated depends on the size of the river, its slope, and the prevailing climatic characteristics. Excess water is eventually disposed of by downstream drainage, water infiltration, and evapotranspiration.
To attain such goal, a partly unpublished data set produced within the framework of the SCOPE-UNEP International Carbon Project (e.g., Degens et al. 1991) was herein employed, seeking to analyze the interrelationship between high discharges (i.e., outstanding overbank events) and the resulting impact on solute concentrations (particularly addressing alkalinity dynamics), in the middle Paraná River, Argentina, which is characterized by a vast floodplain. The data suite includes the occurrence of an exceptional ENSO-triggered overbank flood, involving samples collected between 1981 and 1984, near the Argentine city of Paraná, ~ 600 km upstream the mouth. Also included and within the same project, there is another data array, collected in 1985, in an expanded downriver survey.
The data series collected within the carbon project was supplemented with another set, here used to explore the fluvial processes affecting alkalinity dynamics. Based on continuous, uninterrupted daily analyses gathered during a decade, the hydro chemical data were collected by Argentina’s Obras Sanitarias de la Nación in approximately the same sampling spot used in the previously mentioned series (i.e., ~ 600 km upstream the mouth). The series comprises hydrological and chemical data, recorded between 1965 and 1975, and—taking advantage of its extended and continuous characteristics—it is used to probe further into the association existing between alkalinity, and the floods (i.e., some of exceptional magnitude) that periodically inundate the ample flood valley of the Paraná River’s middle range.
Main features of the Paraná River
The Paraná River and its tributaries account for the largest proportion (~ 81%) of the Río de la Plata drainage basin (~ 3.17 106 km2), pertaining the remainder area to the Uruguay River drainage basin (Fig. 1). In terms of basin area (~ 2.58 106 km2), the Paraná River occupies the fifth place among the global rivers that discharge more than 400 km3of water annually (Milliman and Farnsworth 2011). It is 4500 km-long and drains a continental-sized drainage basin formed by several contrasting regions in four different countries (i.e., Brazil, Paraguay, Bolivia, and Argentina), with an assortment of mountain chains, rainforests, deserts, and savannas (Fig. 1), thus configuring a dissimilar scenario: from Andean sources close to South America’s Pacific active margin, in the Bermejo and Pilcomayo upper catchments (~ 65°W), to the tropical headwaters placed at the Serra dos Preneos (~ 45°W), close to the Atlantic passive margin. The Gran Pantanal (i.e., 0.2 × 106 Km2, one of the largest wetlands in the world at ~ 15°–17°S, and ~ 55°–60°W) is an additional headwater that exerts a discernible modulating effect on the Paraguay River, which joins the Paraná near the Argentine city of Corrientes, where its middle reach begins.
Maximum precipitation (2400 mm y−1) occurs along the eastern edge of the basin and over the Iguaçu River drainage basin. Rainfall decreases (400–800 mm y−1) towards the western edge, along the 60–65°W strip. In general, runoff mimics rainfall distribution, with high values along the drainage basin’s NE corner (700–800 mm y−1), and in the Bermejo and Pilcomayo upper catchments (~ 500 mm y−1). In Argentine territory, the Paraná’s upper and middle course has a mean runoff of ~ 300 mm y−1. Potential evapotranspiration at the origin of Paraná’s middle course is ~ 1000 mm y−1and gradually decreases to 850 mm y−1, at the mouth.
Most of the Paraná River drainage network seems to have originated in the Late Cretaceous, in synchrony with the opening of the Atlantic Ocean. Its mouth, however, switched to the present Río de la Plata estuary, about 2.4 My. Its structural setting is a classic intra-cratonic layout for much of its course; its main geological features are defined by Upper Paleozoic and Mesozoic sediments and extensive volcanic flood-basalts constrained by Precambrian crystalline rocks (Potter and Hamblin 2006).
The Paraná basin’s hydrographic net is a complex system that transports water down to the middle latitudes of the South Atlantic Ocean, collecting and modifying inorganic and organic materials from mountainous as well as from low-relief tropical environments. Iriondo et al. (2007) have dealt extensively with the Paraná’s features, in general, and particularly with those of its middle stretch.
Data and methods
Argentina’s Sistema Nacional de Información Hídrica allows to download permanently updated Paraná River discharge data from different discharge (or stage height)-measuring stations placed along the Paraná main stem and tributaries (https://snih.hidricosargentina.gob.ar/Inicio.aspx). As indicated in the text, data from four gauging stations (i.e., Corrientes, La Paz, Paraná, and Rosario) placed along the Paraná’s main channel have been used throughout this paper.
Parametric statistics, such as regression and correlation analysis, require that the variables under study adjust to a normal distribution. Discharge and solute concentrations often show a skewed statistical distribution, which can be normalized by converting to logarithms. This procedure has been followed wherever necessary.
Discharge data were deseasonalized by subtracting the mean historical discharge of a specific month from the measured discharge for the same month in the data series: QiD = Qi −Qmi, where QiD is the deseasonalized discharge of the ith month; Qi, is the measured mean monthly discharge for the ith month, and Qmi is average historical discharge for the ith month.
The downriver flood wave velocity—between the stage meters placed at La Paz (757 km upstream the mouth) and Rosario (420 km upstream the mouth) during the 1982–1983 ENSO triggered outstanding flood—was determined by employing the cross-correlation statistical technique (e.g., Davis 1986). The method is appropriately used to compare two time-dependent series, thus revealing the strength of such relationship, and the lag or offset in time between them at their position of maximum equivalence.
Water surface slopes (WSS) were determined using the water heights recorded in the stage meters placed at La Paz (757 km upstream Paraná’s mouth) and at the city of Rosario (420 km upstream Paraná’s mouth). Both parameters are also reported by the Sistema Nacional de Información Hídrica of Argentina. The employed simple equation was, SWSS = (HLP - HR)/DLP-R, were SWSS is the WSS, HLP and HR are La Paz and Rosario stage meter readings, respectively, and DLP-R is the distance between La Paz and Rosario (337 km). The relative gauging station heights were transformed to sea-level values by applying the corresponding numerical corrections (Soldano 1947).
As stated above, three different data suites have been used to tackle this paper’s subject matter. They were the only available data series for the Paraná River, which contained physicochemical information associated with river discharge measurements. The main data set was gathered between 1981 and 1984 in the middle Paraná, sampled 600 km upstream the mouth during the progress of the SCOPE-UNEP International Carbon Project. This data set was accompanied with another array obtained in a downriver exploration (Depetris and Kempe 1993), from the Iguazu falls (i.e., 1927 km upstream the mouth), down to the dock of the city of Paraná (i.e., 600 km upstream the mouth). This project, which had its main seat at Univeristät Hamburg (Hamburg, Germany), was originally initiated to gather detailed information on the dynamics of inorganic and organic carbon species in world rivers (e.g., Degens et al. 1991, and references therein). The methodologies for various methods used in the field, anions, cations, and assorted carbon species have been described by Michaelis and Ittekkot (1982). Data on the main inorganic constituents are reported here for the first time, whereas the riverine dynamics of various carbon species has been dealt with elsewhere (Depetris and Kempe 1993).
The AqionFootnote 1 hydrochemistry software (https://www.aqion.de/site/98) was employed to check for charge balance errors (CBE) and to calculate several variables (e.g., TDS, Eh, ionic strength, etc.). Most CBE in both data sets assembled within the framework of the SCOPE-UNEP International Carbon Project fluctuated between − 4.7% (deficiency of cations) and 4.9% (deficiency of anions).
The added data series was selected based on the need of using a long and uninterrupted data series to probe into the mechanisms linking alkalinity with the level reached by water in the floodplain (i.e., discharge variability). A 10-year long time series (1965–1975) of daily chemical analyses performed in the Paraná River (Lenardón 1979), at the city of Paraná, sampled about 600 km upstream from the mouth, was used to probe into the hydrology–alkalinity relationship. The chemical analyses were performed in the laboratories of Obras Sanitarias de la Nación, Argentina’s federal agency which, at that time, was in charge of the daily quality control of river water, subsequently processed to attain potable quality, and distributed for human consumption through municipal networks.Footnote 2 Monthly concentration (geometric) means were calculated from daily measurements. This extended series included several chemical parameters, which were determined simultaneously (i.e., pH, TDS, color, turbidity, water hardness, sulfate, alkalinity, chloride, etc.), permanently subjected to strict quality controls. However, only alkalinity and chloride concentrations were employed in this work. Alkalinity was determined by standard 0.1 N H2SO4 electrometric titration; precision was checked every ten samples, and was within 2.1% (p < 0.001). The well-known Mohr method (i.e., titration with a AgNO3solution) was used to measure Cl−concentrations; precision was checked every 20 samples, and was within 1.9% (p < 0.001). Lenardón (1979) supplied more detailed analytical information.
Hydrological outline of the Paraná River
The Paraná’s middle reach originates when the river—with headwaters in tropical Brazil—meets the Paraguay River, near the Argentine city of Corrientes (i.e., 1208 km upstream the mouth), and extends downstream for ~ 800 km (i.e., until the city of Rosario), with a floodplain width that fluctuates between ~ 20 and ~ 50 km (Fig. 2). Although it accounts for about ~ 1.5% of the total drainage basin’s area, the extensive wetland is important in terms of biodiversity and as a significant factor affecting the riverine biogeochemistry.
Countless lentic and lotic water bodies of assorted shape, size, and age fill the middle Paraná floodplain (Fig. 2). Modern and evolved meanders, and anastomosed plains are the main geomorphological units (Paira and Drago 2007). These features are embedded in a heterogeneous mosaic of water bodies, with landscapes determined by the variable dynamics of the fluvial processes, and the short- and long-term evolution of the river floodplain (Fig. 2). The Paraná’s floodplain is inundated and partially drained periodically following the river’s seasonal discharge variability. A flood may barely enter the floodplain or—when reaching a very high stage—it may inundate entirely the distance across the riparian environment. Excess water on the floodplain drains back to the channel as the river discharge recedes. On wide floodplains—such as the Paraná’s—bordered by natural levees, the water may drain back slowly, causing local inundation or pounding which may last for months.
The Paraná River currently delivers to the SW Atlantic a mean discharge of ~ 17000 m3 s−1 (i.e., ~ 540 Km3 annually), and shows a statistically significant increasing discharge trend since the 1970s, as well as an active remote connection with El Niño-Southern Oscillation (ENSO) events in the Pacific Ocean (e.g., Depetris et al. 1996; Pasquini and Depetris 2007, 2010). The teleconnection linking the Southern Oscillation (SO) and Paraná River discharges was originally recognized by Sir Gilbert Walker’s research group, back in the 1920s, when they were pursuing the prediction of India’s monsoons (e.g., Depetris et al. 1996, and references therein). The El Niño occurrence in the Pacific Ocean frequently triggers—among several other global climatic impacts—exceptionally abundant rainfalls in the Brazilian headwaters of the upper Paraná and Paraguay rivers. Since El Niño episodes are usually in phase with the Paraná’s seasonal high-water period (i.e., during December–March, the austral summer), its occurrences frequently result in overbank floods—sometimes of exceptional magnitude. La Niña events, on the other hand, often result in below-the-mean discharges, usually during the southern summer.
An aspect worth emphasizing is that, although the upper Paraná River provides an average of ~ 70% of the water reaching the river’s middle reach (Pasquini and Depetris 2007), the Paraguay River increased its relative discharge contribution to the middle section of the Paraná River, during the 1982–1983 high flood (Pasquini and Depetris 2010). However, most of the total suspended sediment (TSS) load being transported to Corrientes is delivered by the Paraguay River and, particularly, by one of its Andean tributaries, the Bermejo River (e.g., Campodonico et al. 2016, and references therein).
Figure 3 shows the Paraná River monthly mean discharge for the period 1980–1985, along with the corresponding deseasonalized discharge series and the Southern Oscillation Index (SOI)Footnote 3(e.g., Stone et al. 1996, Sarachik and Cane 2010). The figure shows the markedly negative SOI value, which preceded the exceptionally high ENSO-caused flood of 1982–1983 in the Paraná River, the highest on record (e.g., Hansen 1990). The flood began in 1982 and lasted for almost 2 years, reaching a peak discharge which nearly touched 60000 m3 s−1at the Corrientes gauging meter, almost four times the Paraná River average annual discharge. The inundation flooded the areas that the USA’s FEMA (Federal Emergency Management Agency) designates as between the limits of the 100-year and 500-year floodplain (i.e., with a 0.2% annual chance of flooding, affecting areas beyond the protection of levees from 100-year flood).
The deseasonalized data series allows to assess further the flood impact. During the considered period (1980–1985), the deseasonalized discharge shows that, at the flood’s peak, it exceeded by ~ 37000 m3 s−1 the historical average discharge for the same period (Fig. 3). This discharge meant a gauge stage height of ~ 9 m, i.e., several meters above the mean hydrograph value at the Corrientes stage meter. It is worth considering that the mean annual (historical) discharge at Corrientes is reached when the stage meter height is ~ 3.2 m (~ 17000 m3 s−1). River water enters or is flushed out of the lentic/lotic environments - overly abundant in the flood plain - when stage readings fluctuates in the ~ 2.9–3.3 m range. A high flood (e.g., ~ 45000 m3 s−1) reaches a stage reading of ~ 7 m at Corrientes, covering extensive areas of the riparian zone with more than a ~ 3 m-deep water mass. A conservative estimate proposes that during the 1982–1983 flooding period (~ 18 months), the valley stored between 200 and 400 km m3of water, which probably signified a contribution of ~ 10–20% to the topmost discharges.
The velocity of propagation of the flood-wave in the middle section of the Paraná River - when the flood reaches a middle stage in the rising limb - is ~ 60 km d−1, and it slows down to ~ 45 km d−1, or less, during the high or very high stage (Soldano 1947). By means of the cross-correlation method, it was possible to establish that, during the 1982-1983 ENSO high flood, it took 9 days to the flood wave to cover the distance (337 km) that separates the stage meters of La Paz (i.e., 757 km upstream the mouth) and Rosario (i.e., 420 km upstream the mouth), progressing downriver at a mean velocity of ~ 49 km d−1 (i.e., ~ 0.6 m s−1). The flood wave, which is slower than the mean water velocity in the main channel, clearly affects the water surface slope (WSS).
The gauge oscillations inherent to the WSS determine the influx or outflow of flood water in the flood plain (Fig. 4). Figure 4a shows that the relationship between discharge (i.e., stage meter height at La Paz) and WSS is a complex one, because WSS may increase with increasing stage readings (e.g., as in the peaks of June 1983) but, also, with decreasing ones, as of July 1, 1984 (Fig. 4a). The latter instance implies that, with decreasing stage heights, the floodplain was being drained due to increased WSS. Conversely, the plunging discharge as of March 20, 1984 (Fig. 4a) appears to determine a significant decrease in WSS, which probably marks a slowed-down draining of the floodplain. At any rate, the draining of the wetland occurs when water level at the main channel descends significantly and WSS maintains a relatively high value (e.g., WSS > 3.8 cm km−1).
It seems clear that the residence time of flood water in the floodplain was of the order of days/weeks during the inundation of 1982-1983, but it can extend months—or even years—during extended periods of low waters, when lentic environments become practically isolated from the main lotic ones. On the other hand, the scatter graph of Fig. 4b displays the complex connection—known as hysteresis—between stage meter height (i.e., discharge) and WSS, at the stage meter of La Paz.
River discharge, soil moisture tension, solute and suspended sediment concentrations experience the occurrence of hysteresis (e.g., Walling and Webb 1988, Baca 2008). However, some aspects of such looped rating curves still remain unclear (e.g., Muste and Lee 2013). Hysteresis in river discharge is most pronounced in flat sloped streams and occurs during unsteady flow when WSS changes due to either rapidly rising or falling water levels in a river control reach. The loops suggest the occurrence of rate-dependent hysteresis (i.e., a dependence of the state of the system on its history),Footnote 4 which shows smaller loops as the discharge increases (i.e., narrower WSS variability), and wider loops in the opposite situation, thus reflecting differences in the dynamics of the water exchange between the riparian zone and the lotic systems (Fig. 4).
The described dynamic water exchange between the main river stem and the extensive floodplain not only leads to significant ecological impacts but also affects the relationship between water volume and solutes or suspended particle concentrations. When large water masses, that have been stored in the floodplain for weeks or months—and, hence, subjected to numerous processes that alter their physicochemical characteristics—re-enter the main channel while undergoing a receding stage, the chemical and physical characteristics of flowing water in the main stem may change, sometimes markedly.
Results and discussion
The geochemical (e.g., Sanci and Panarello 2018; Campodonico et al. 2015, 2016; Depetris and Pasquini 2007; Pasquini and Depetris 2012; De Cabo and Seoane 2005; Depetris 1976), and biogeochemical characteristics (e.g., Ceballos et al. 2013; Depetris 2005; Villar et al. 1998; Depetris and Kempe 1993; Depetris and Paolini 1991) of the Paraná River have been studied for several decades. The vast and intricate wetland that comprises its middle reach has received special attention not only due to the complexity of its ecosystem, and to partly clear biogeochemical features, but also because there is a need to improve knowledge on its functioning, of utmost importance when human intervention must be dealt with.
The geochemical signature of dissolved and particulate phases
Dissimilar geology, climate, topography, and biota characterizes each of Paraná’s three main headwaters (i.e., Andean Bermejo and Pilcomayo rivers; Paraguay’s Gran Pantanal, and upper Paraná’s tropical mountainous ranges), and such attributes results in different geochemical features in the total suspended solids (TSS) as well as in the dissolved phases. The middle Paraná sediment load bears a signature of one source supplying “old or recycled materials affected by intracrustal differentiation”, and a secondary source of “young material derived from undifferentiated volcanic rocks” (Compodonico et al. 2016). This is also succinctly shown by radiogenic isotopic data. Figure 5 shows differing isotopic signatures in the Paraná River for the dissolved and particulate species, whereas the Uruguay River samples (i.e., included for comparison), with a relatively uniform lithology (i.e., dominant tholeiitic flood basalts), do not (Henry et al. 1996). Paraná River TSS is significantly more radiogenic (e.g., 87Sr/86Sr, 0.723–0.726) than its dissolved counterpart, and has low 143Nd/144Nd ratios (e.g., 0.5120–0.5121, and negative εNd (0)), typical of an enriched crustal source. Conversely, the dissolved fraction is somewhat less radiogenic (e.g., 87Sr/86Sr, 0.7120–0.7124), maintaining a negative εNd (0) and lower 143Nd/144Nd ratios (e.g., 0.5120–0.5122) (Henry et al. 1996). These isotopic differences are probably related to the diverse sources supplying the largest proportion of the sediment load (i.e., the Bermejo River) and the major water source (i.e., the upper Paraná drainage basin). Data from the southern Puna (Gili et al. 2017) and from Amazonian sediments (Rollinson 1993) plot halfway between both clusters. Contrastingly, the Uruguay River data are compatible with Paraná flood basalts (Faure 1986), and does not show significant differences in its isotopic signatures, regardless of its particulate or dissolved nature (Fig. 5).
The scatter plot of Fig. 6 seeks to approach the provenance of dissolved phases in the middle Paraná River during the 1982–1983 flood. The record has been separated into one set including data preceding and following the flood (i.e., lower discharges) and another set collected during the high flood. Most of the plotted data is bounded within four straight lines resulting from the chemical reconstruction of source minerals in the Sierra Nevada (California and Nevada. USA) (Garrels and Mackenzie 1967). Two lines represent the ideal hydrolysis of a mixture of plagioclase (175 mol) + biotite (14 mol) + calcite (115 mol) + H2O + CO2 under conditions of deep circulation (i.e., groundwater, extended rock–water interaction). One line stands for the covariation of HCO3− and Ca2+, whereas the other represents the covariation of Mg2+ and Ca2+, both normalized to Na+.
The other two lines represents the ideal dissolution occurring in near surface conditions, of a combination of plagioclase (177 mol) + biotite (7.3 mol) + potassium feldspar (13 mol) + H2O + CO2 (i.e., ephemeral springs, limited water–rock interaction) (Garrels and Mackenzie 1967). As in the previous instance, one stands for the covariation of HCO3− and Ca2+, whereas the other represents the covariation of Mg2+ and Ca2+, both normalized to Na+.
The scattering of the data suggests a pronounced lithological variability in the sources, as well as dilution, and unevenness in the rock-water interaction. The dynamic exchange between the floodplain and the main channel is also a likely significant cause.
According to Gaillardet et al. (1999), waters draining limestone/carbonate would plot at or near the upper right corner of the graph, whereas waters draining hypersaline terrains/evaporites would fall in the graph’s lower left corner. Solutes from pure silicates sources would plot above the uppermost lines, with Ca2+/Na+ plotting in the ~ 0.3–0.7 range.
Revisiting the main hydro chemical characteristics during high flooding
Table 1 shows data gathered between 1981 and 1984, when the Paraná River was subjected to one of the highest (and most disastrous) floods on record: the ENSO-set off exceptional flood of 1982–1983 (e.g. Depetris and Kempe 1991). Table 1 presents variables and parameters herein chosen to project an image of the system’s response to extreme flooding.Footnote 5
During the high flood, data showed that a five-fold increase in discharge (i.e., from 10000 to 50000 m3 s−1, at the Corrientes gauging station) determined a mean TDS dilution of ~ 350%. Average conductivity (i.e., corrected for temperature) fell from ~ 225 to 64 µS cm−1. The coefficient of determinationFootnote 6 (r2 = 0.402) for the nonlinear regression implies that only ~ 40% of the variability of the total dissolved solids (TDS) is accounted for by the discharge determined at the Corrientes stage meter and that other factors would explain the remaining ~ 60% of the variance of the dependent variable. Likewise, in Fig. 7a, ionic strength peaks (7–8 mM) at low discharge and then sharply decreases (1–2 mM) with high flooding, reaching values close to those exhibited by rainfall. Along this line of argumentation, the Na+/Cl− molar ratio in Paraná River water (Fig. 7b) exhibited a mean of 0.76 ± 0.8Footnote 7 during several months previous to the high flood, and reached a mean of 1.4 ± 0.9 during the ENSO-triggered flood. The inundation left a lasting “memory effect”, because after the event, the Na+/Cl− molar ratio in river water (Fig. 7b) reached a mean of 1.3 ± 0.3, which persisted for several months. It must be emphasized that, according to Möller (1990), the Na+/Cl− molar ratio of continental rainfall fluctuates between 1.1 and 1.8 (i.e., not influenced by excess Na and Cl), although the molar Na+/Cl− ratio in bulk maritime rainwater is ~ 0.86.
Meybeck (2005) used the parameter TZ+ [TZ+ (meq L−1) = Na+ + K+ + 2Ca2+ + 2 Mg2+] to interpret river chemistry. Some samples analyzed in the Paraná during the 1982-83 flood plot within the dilute field (0.375 < TZ+ < 0.750 meq L−1), although most samples measured during the flood fall within the medium dilute field (0.750 < TZ+ < 1.500 meq L−1), and only two samples plot in the medium mineralized domain (1.500 < TZ+ < 3.000 meq L−1). The samples determined before and after the ENSO flood are more concentrated to some extent, reaching the mineralized field (3.000 < TZ+ < 6.000 meq L−1) at low flow (Fig. 8). In this instance, flood-induced dilution obviously explains low concentrations. Some medium mineralized waters were probably accounted for by the relative increase in the water volume supplied by the Paraguay River system (i.e., the upper Paraguay plus its Andean tributaries). At any rate, Figs. 7 and 8 are examples of the low correlation that prevails between river discharges and physicochemical variables, which is another characteristic feature—besides pronounced dilution—of high floods in large rivers with vast flood plains.
Particulate matter transported in suspension (TSS) also shows ample variability, as dissolved phases do. Relatively low TSS concentrations are ubiquitous during the flood, reaching values that were common before the flooding event (Fig. 9a). The highest concentrations are reached in the ~ 17000–30000 m3 s−1 flow range, regardless the conditions governing the discharge (i.e., before, during the flood, or afterwards). These concentrations are probably caused by the flushing out of the floodplain.
Particulate organic carbon (POC) is also very variable in all river stages (Fig. 9b), although this characteristic is particularly noticeable in the ~ 17000–30000 m3 s−1 discharge span, where organic matter sources may be terrestrial debris as well as phytoplankton. At high discharges (Q > 35000 m3 s−1) POC concentration remains < ~ 100 µM and POC/PN maintains the mixed sources signatures for the transported organic matter (Fig. 9b).
Probing further into the high-flood discharge vs. concentration, it is important to explore the influence of WSS in governing the hydro chemical dynamics during exceptional flooding and the role played by the water exchange mechanism with the floodplain.
WSS appear to show a discernible linkage with some biogeochemical variables in as much the former is associated with the draining of the floodplain. Dissolved inorganic carbon [DIC = (CO2 (aq)) + (H2CO3) + (HCO3−) + CO32−)]Footnote 8 is a relevant example. Figure 10 shows the clustering of DIC concentrations that prevailed preceding the flood (i.e., Pre-ENSO), whereas higher concentrations are recorded during the flood and after its occurrence, when the floodplain is drained due to higher WSS and decreasing water level. Increased heterotrophic respiration in the floodplain water bodies leads to increased DIC by supplying CO2:
The well-known mechanism is further corroborated in Fig. 11. The level reached by the CO2 partial pressure (PCO2) in Paraná’s flood water supplied another angle to understand the flooding/draining process of the floodplain. PCO2 is very high during the high flood and after its occurrence, when the floodplain is drained as a consequence of increased WSS associated with decreasing water levels. Figure 11 also shows exceedingly high PCO2 values (~ 8000– ~ 16000 ppmv) Footnote 9 associated with above-the-mean discharges (i.e., > 17000 m3 s−1). The wide span of the variation leads to different scenarios: one when the river was in the rising limb (lower PCO2), and another when discharge was in the downward limb of the hydrograph.
Accordingly, the dynamics of the flood determined a decrease in pH to below-neutral values when overbank discharge reached ~ 20000 m3s−1 and flood water, mainly acidified by the high PCO2 increase and other processes occurring in the wetland, was flushed out from the flood valley (Fig. 12). As water level decreased and organic-rich ox-bows and ponds in the riparian environment became shallower, the oxidation of sulfur may have also contributed to lower the pH:
The dynamics of carbon and its sources in the Paraná River has shown, among other findings that dissolved organic carbon (DOC) and the inorganic fraction (DIC) were essentially uncorrelated with Paraná’s discharge during the 1981–1984 period (i.e., 1982–1983 ENSO flood included) (Fig. 13): DOC showed high concentrations associated with both, low and high discharges, whereas DIC exhibited a narrower variability. In fact, the coefficient of variation (i.e., cv = σ/μ) for DOC was ~ 0.87, and cv ≈ 0.47 for DIC. Furthermore, the DIC/DOC ratio was 0.4 ± 0.34 for the period preceding the flood, 1.14 ± 0.7 during the high flood, and 1.68 ± 1.0 after the flood. These values further suggest that bacterial respiration is a significant part of DIC in the water drained from the riparian environment.
Table 2 shows contrasting dynamics for some important biogeochemical parameters during the pre-ENSO, ENSO, and post-ENSO (flood) periods. TDS, TZ+, and DOC showed dilution throughout the flooding process, whereas DIC and PCO2 exhibited an increasing concentration trend during the whole 1982–1983 flooding event. Clearly, the contribution of PCO2 to DIC appeared as more important during the flood and in the following receding stage than in the preceding period.
Scientific literature shows that the silica cycle has significant overlap with the carbon cycle (e.g., Berner et al. 1983). In the riverine environment, SiO2 is particularly subjected to biological consumption (e.g., diatoms, radiolarians) and to other physicochemical reactions, particularly while river water remains isolated in the lentic environment. The dynamic water exchange between floodplain and the river main channel during the Paraná’s flood of 1982–1983 revealed, however, a discernible signal. Preceding de high flood, the geometric mean of SiO2 concentrations (± standard deviation of normalized data) was 229 ± 1.3 μmol L−1; during the ENSO-caused flood, the concentration increased to 265 ± 1.1 μmol L−1, and during the receding stage it decreased to 178 ± 1.4 μmol L−1. Since apparently there was no significant dilution after the high flood, the decrease observed during the declining stage can only be attributed to the dilution exerted by SiO2-depleted flood plain water entering the main stem.Footnote 10
Within the framework of the SCOPE-UNEP Carbon Project, a downriver biogeochemical probe was performed in July–August 1985, after the high flood of 1982–1983 (Table 3). The attention was placed on the biogeochemistry of carbon (Depetris and Kempe 1993) even though other hydro chemical data was also collected. The downriver survey showed a generalized concentration increase—in the upper as well as in the middle Paraná River reaches—in most dissolved chemical elements, with some conspicuous exceptions (e.g., PO43−) (Depetris and Pasquini 2007; Pasquini and Depetris 2012). In general, these investigations showed the geochemical influence of the Paraguay River and its tributaries, not only in the dissolved and particulate inorganic load of the middle Paraná stretch but also in its carbon biogeochemistry (Depetris and Kempe 1993). More recent studies (Campodonico et al. 2015, 2016) also showed that physicochemical inhomogeneity is not only observed downriver but also crosswise. This transverse chemical asymmetry is mainly caused by the incomplete mixing of the Paraguay and Paraná rivers, which is perceived for over 200 km downstream their meeting point (Campodonico et al. 2015). The use of 222Rn also showed the likelihood of modest groundwater contributions (Campodnico et al. 2015).
Figure 14 illustrates the influence of the Paraguay River on the Paraná’s middle section by means of TZ+ parameter. It also shows the effect of the floodplain’s lotic and lentic environments on the river’s main stem. Table 3 shows how inorganic constituents can be concentrated by evapotranspiration, and how biogeochemical components can be altered while isolated in the riparian environment. Similarly, Bonetto et al. (1998), and Villar et al. (1998) have compared the hydrochemistry of the lower Paraná’s main stem and the adjacent swampy floodplain and have shown the biogeochemical changes—particularly concerning nutrients—experimented in the riparian environment of the lowermost Paraná’s reach.
Long-term variability of solute concentration in the Paraná River
As has been described, the concentration of dissolved and particulate phases in the middle Paraná River water is, in general, poorly correlated with discharge, partly due to the water exchange process (i.e., regulated by stage height) between the main channel and the riparian zone. Flood water—while in the floodplain—endures chemical (e.g., it may concentrate and precipitate mineral phases), biological (e.g., biological production regulates dissolved gases), and physical (e.g., turbidity and color affect light penetration) changes while residing—for weeks or months—in the riparian environment. When the mass of water stored in the floodplain for a relatively long period of time re-enters the main channel, it modifies the river water physicochemical signature.
The availability of a 10-year long, uninterrupted time series (Lenardón 1979), allowed to further explore aspects of the discharge-concentration relationship. A relevant example is depicted in Fig. 15, where mean Cl− and TDS concentrations are plotted against river discharge. Over the 10-year period, TDS exhibited a weak correlation with discharge (r = 0.16, p < 0.1) and, hence, a very low percentage of its variance is accounted for by the independent variable. On the other hand, the correlation of Cl− (i.e., considered a conservative element) with discharge is higher than with TDS (r = 0.45, p < 0.001) and the independent variable (i.e., discharge) accounts for ~ 20% of its variability. The relationship is not linear and deviates markedly—as all large rivers do—from the ideal dilution model (i.e., twice the discharge leads to one-half the solute concentration). During the 1982–1983 flood, most of the Cl− concentration variance remains unaccounted for, inasmuch river discharge “explains” only ~ 24% of its variability.
Figure 16 shows the monthly variation of discharge and alkalinity during the 10-year period (1965–1975) used to analyze the discharge—alkalinity relationship in the middle Paraná. A cursory inspection of the graph appears to show that the coherence between discharge and alkalinity is somewhat restricted to high water events (e.g., the strong El Niño-triggered floods of 1966 and 1973). Other floods (or low-water periods), not necessarily connected with ENSO events, may or may not be correlated with alkalinity concentration. Although reduced during low river stages, the connections between the floodplain and the main stem remain almost permanently operative. High alkalinity concentrations are also discernible associated with some low-discharge periods (e.g., often connected with La Niña events). During such phases, the relative importance of the Bermejo and Pilcomayo rivers as discharge suppliers to the middle Paraná increases, as also does carbonate alkalinity.
Moreover, correlation between both, alkalinity and discharge, is not significant (p >0.01). Correlations were low between discharge and other variables routinely used in water analysis, like, TDS—as seen above—turbidity (r = − 0.148, p < 0.05), and filtered water color (r = 0.471, p < 0.001) (Lenardón 1979).
Alkalinity and the factors affecting its concentration in the middle Paraná River
Properly defined, total alkalinity is “the equivalent sum of the bases that are titratable with a strong acid” (e.g., Stumm and Morgan 1996, Albarède 2009). In terms of molar concentrations, total alkalinity (AT) is equal to,
where m is the molar concentration. In most natural waters, only carbonate and bicarbonate ions are of significance, because, in comparison, the other ions exhibit very low concentrations. Accordingly, the previous equation shortens to:
Therefore, in most natural waters, total alkalinity is approximately equal to carbonate alkalinity (e.g., Drever 1997; Langmuir 1997). However, in large rivers with extensive floodplains (e.g., the Paraná River), where large water volumes may be stored for significant periods of time, a number of processes, which may modify alkalinity concentration may grow in importance and contribute to the modification of alkalinity concentration.
Given the lithology and climate dominating Paraná’s western upper catchments (i.e., the Bermejo and Pilcomayo rivers), it is likely that the prevailing reaction controlling AT production in the Andean headwaters might be the dissolution of carbonate rocks, which results in increased AT:
Likewise, in the Brazilian and Paraguayan tropical headwaters, rock weathering (i.e., hydrolysis of silicates) is surely important, in reactions like the weathering of plagioclase, which also increases AT:
Upon completion, this well-known reaction produces kaolinite as the only solid product. Other reactions, such as nitrification and denitrification—among others—may contribute to increase or decrease AT in the Paraná’s main stem.
The 10-year long data time series (Lenardón 1979) was employed to approach the interpretation of the discharge–alkalinity relationship in the middle Paraná River. To improve its understanding, the following graph (Fig. 17) was constructed with AT geometric means and discharge (Q) values for an average year. (i.e., of the studied period, 1965–1975).
A significant covariance between Q and AT is observable in Fig. 17 for the period January–July. Summer (austral) rains mobilize the products of mineral weathering in the drainage basin which are, most likely, the main factors increasing AT. It is probable that during the first half of the year, average AT is basically carbonate alkalinity, which distinctively covariates with mean monthly Q. At peak discharge, it is noticeable a lag between both variables: mean Q leads mean AT, reaching its maximum in March, whereas AT attains its peak concentration in April. This lag between discharge and concentration of different chemical species in river water has been observed and studied for several decades (e.g., Godsey et al. 2009; Hunsaker and Johnson 2017).
During (austral) winter and early spring, both variables diverge markedly. As considered before, low water stage in the middle Paraná means that the abundant lotic and lentic water bodies in the Paraná’s floodplain undergo a draining process—activated by increasing WSS—and a very substantial water volume is reintroduced into the main channel (i.e., likely over 10% of the river discharge).
During the time spent in the floodplain’s riparian scenario, the stored water experienced several biogeochemical modifications and, therefore, the flashed out floodplain water bears a different signature, particularly through several reactions that affect alkalinity. For example, due to the consumption of H+, AT increases through denitrification and by means of the assimilation of nitrate ions into photosynthesis:
Supporting this view, Villar et al. (1998) found, in lentic bodies of the lower reach of the Paraná River (i.e., downstream Rosario, 420 km upstream the mouth), a fast decrease in NO3− concentrations in lentic waters, suggesting large losses by denitrification. Likewise, Bonetto et al. (1998) found a N-NO3−concentration of 20 ± 8 µg L−1in marshy environments, and 197 ± 18 µg L−1in the main river channel.
Another mechanism likely to participate in AT increase is the reduction of SO42−, which may participate in relatively deep (i.e., anoxic) water bodies:
Bonetto et al. (1998), in the comparison of lentic and lotic environments in the Paraná’s lower reach, found a significant decrease in SO42− concentration (5.4 ± 0.8 mg L−1) in floodplain’s marshy environments as compared with the concentration recorded in the main river channel (8.4 ±1.0 mg L−1). The CO2 concentration increase observed in Fig. 11 further endorses the likelihood of the occurrence of reduction reactions. It may partially explain the high PCO2 levels reached during the post-flood draining of the riparian zone.
In September, austral spring restarts the assimilation of NO3− associated with the photosynthesis processes, causing AT to increase due to H+ consumption; AT-rich waters due to the stimulated photosynthetic activity in riparian ponds and ox-bows (i.e., turbidity decreases in stagnant waters and primary productivity increases), re-enters the Paraná’s main stem. Additionally, reduced discharge frequently accompanies increased concentrations of the nutrient pool. Villar et al. (1998) have shown that—in the Paraná’s lower reach—concentrations of soluble reactive phosphorous were higher in the floodplain’s lotic bodies than in the main channel.
Nonetheless, the processes of photosynthesis and respiration are coupled by assimilation of NO3−, NH4+, and HPO42−. The assimilation of NH4+ during photosynthesis causes the production of protons, which directs to a decrease of AT in the floodplain’s ponds and oxbows and, hence, in the water masses, introduced later into the main stem:
In November–December, Q started a swelling rate and AT also begun the austral summer incipient increasing trend, mobilizing the products of rock weathering (i.e., due to summer rains) and dissolution of carbonate rocks in the river’s upper catchments.
The mean hydrograph obtained for the 1965–1975 time period, and the average AT computed for each month of the synthetic hydrological year, allowed to produce the scatter graph of Fig. 18. The graph shows that, in general, AT tends to decrease with below-the-mean Q,Footnote 11 whereas the trend becomes positive for above-the-mean discharges. It has been shown above that low discharges stimulate the draining of the floodplain’s lotic and lentic water bodies, where different biogeochemical processes define changes in the chemical composition of the temporarily stored water mass, which is reintroduced in the main channel during the decreasing stage. This is the reason why the mean AT concentrations of August, September, and October are clustered in the decreasing trend of Fig. 18. It seems plausible to assume that in the middle Paraná River, during the low-water months, floodplain-supplied AT masks to a certain extent the AT signal brought downstream from upper reaches.
Summarizing and concluding remarks
The Paraná River is among the largest fluvial systems in the Americas with tropical as well as Andean semiarid headwaters. Most of its present course originated in the Late Cretaceous, in irregular synchrony with the opening of the Atlantic Ocean (Potter and Hamblin 2006). Its hydrology exhibits a working teleconnection with the occurrence of ENSO phenomena in the Pacific, which usually results, with average frequency of two to seven years, in high floods (El Niño) or atypical low discharges (La Niña) (e.g., Depetris et al. 1996). High floods affect, above all, the middle and lower Paraná, which is characterized by a vast floodplain. Yearly inundations impact in various ways on the riparian environment that blankets the flood valley, particularly from a biogeochemical point of view. Hydrological seasonality rules a dynamic water exchange between lentic environments prevailing in the flood valley, and lotic conditions of countless streams that carve the floodplain, and the main river stem.
The upper Paraná River supplies 65–75% of the middle stretch discharge, whereas the Paraguay—and mainly its Andean tributary, the Bermejo River—deliver a similar proportion of the total solid load. Therefore, the middle Paraná water has a chemical signal which is similar to the upper Paraná, while the geochemical signature of the sediment load conveys a dominant Andean mark. This characteristic is shown by using 87Sr/86Sr and 143Nd/144Nd, which separates the provenance of water and sediment into different sources. A Na-normalized mixing diagram shows that most water samples plot within the boundaries determined by the ideal dissolution lines of mixed minerals, suggesting as well, the occurrence of a varied residence time pattern in the rock-water interaction.
Data gathered during the 1982–1983 ENSO-triggered flood showed that among its main effects was TDS dilution, decreasing concentrations from ~ 225 to ~ 64 µS cm−1 during the peaking flood. Most conspicuous was the marked decrease in pH (~ 6.5), concurrent with an extraordinary increase of PCO2 (~ 16000 ppmv), caused by flood water which had been stored in lentic water bodies for significant periods of time and flowed back into the main stream following the high stage. The Paraná River, like any river (e.g., Butman and Raymond 2011), but particularly those with vast flood valleys with abundant riparian vegetation, tends to be CO2-supersaturated when compared with the atmosphere. The Parana is, therefore, a permanent source of atmospheric CO2 but—as shown—its evasion was especially significant during the 1982–1983 extraordinary flood.
Water mostly remained in the medium dilute water-type (Meybeck 2005) throughout the inundation period, dominated by alkalinity among the negatively charged components. The correlation of discharge and solutes concentration became blurred during the high flood, and Cl− concentrations, which frequently exhibits significant coherence with discharge, is a good example of the above assertion. The interpretation of this image is that, in the middle Paraná River and during high floods -and after their occurrence-, concentrations are controlled by the dynamic water exchange between the main channel and the contiguous wetland.
In low-slope rivers with fully developed floodplains—like the Paraná—WSS is an important factor during flooding, because its fluctuations usually accompany the inundation and drainage of the floodplain during high flood events. The control of WSS is particularly evident with DIC and PCO2, when high concentrations are reached at peaking flood, and during the descending stage, when flood water is drained from the vast wetland.
DOC shows high concentration during both, low and high water. These episodes of high concentrations (~ 20–35 ppm, or ~ 1.7–2.9 mM) alternate with somewhat extended periods of relatively constant low concentrations. These peak concentrations are interpreted as sporadic DOC contributions from the wetland. On the other hand, DIC remained relatively constant throughout the flood and the preceding low-water stage, leading to conclude that DOC was not mainly respired and converted into CO2 by bacteria. Therefore, the already mentioned high PCO2 originates, most likely, in the respiration of primary heterotrophs mainly consuming particulate organic debris (Depetris and Kempe 1993).
A long series (1965–1975) of continuous discharge and solute measurements performed in the middle Paraná River (Lenardón 1979) was used to develop a scheme to elucidate the role played by water level variability during floods and the concentration of alkalinity, which is a chemical variable that—in wetlands—plays an important role in the biogeochemistry of carbon.
Several biogeochemical reactions occurring mostly in the Paraná’s lentic realm—fully developed in the riparian zone—appear to be significant factors in controlling the variability of AT concentrations determined in the middle Paraná main stem or riparian lotic system. Photosynthesis/respiration, nitrification/denitrification, and sulfide oxidation/sulfate reduction are mechanisms that, superimposed on the main processes supplying AT in a fluvial system (i.e., rock weathering reactions) can increase or decrease AT depending on the hydrological stage. Although the relative significance of each mechanism remains unknown, this exercise should be seen as an approach to understand the association between the river’s fluctuating hydrological stage and the resulting biogeochemical processes.
Notes
This software used to validate aqueous solutions operates with the well-known USGS’s PhreeqC as an internal numerical solver.
The sanitary services delivered by Argentina’s Obras Sanitarias de la Nación were privatized in 1992. .
The Southern Oscillation Index (SOI) is a measure of the strength of the Walker Circulation, and one of the key atmospheric indices for assessing the strength of El Niño (i.e., negative index) and La Niña events (i.e., positive index).
In mathematical terms, the response to an external effect is a doubled-valued function. One applies when the effect is increasing, while the other operates when the influence is decreasing.
Additional chemical information collected during the SCOPE/UNEP Carbon Project is included as supplementary material.
The statistic r2 is the proportion of the variance in the dependent variable that is predictable from the independent variable.
Mean ± standard deviation.
(CO2 (aq)) + (H2CO3) are often expressed as (CO *2 ).
ppmv = parts per million in volume.
The differences among geometric means were statistically significant..
The mean discharge in the middle Paraná River for 1965–1975 was ~14500 m3 s−1. Discharges began to increase in the 1970s and, currently, mean annual discharge reaches ~17000 m3 s-1(e.g., Pasquini and Depetris 2007).
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Depetris, P.J. Revisiting the effect of extreme flooding on the chemistry of a large floodplain river: the example of Argentina’s middle Paraná. Environ Earth Sci 80, 54 (2021). https://doi.org/10.1007/s12665-020-09309-4
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DOI: https://doi.org/10.1007/s12665-020-09309-4